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       Herald Strauss

       Institut für Geologie und Paläontologie, Westfälische Wilhelms‐Universität Münster, Corrensstraße 24, 48149 Münster, Germany (hstrauss@uni‐muenster.de)ORCiD code: 0000‐0003‐2639‐1225

      ABSTRACT

      The sulfur isotopic composition of marine sediments and sedimentary rocks reveals a wealth of information about sulfur cycling on different spatial and temporal scales. Sulfate minerals such as gypsum/anhydrite, barite or carbonate‐associated sulfate provide a temporal record of seawater evolution that reflects secular changes in the global sulfur cycle. Dissolved porewater sulfate and sulfide, but more so sedimentary iron sulfides and/or organic sulfur reveal details about the diagenetic evolution of marine sediments. Mass‐independent sulfur isotope anomalies have proven to be a prime recorder for the atmospheric oxygen abundance in the first half of Earth’s history.

      Sulfur is present in the ocean‐atmosphere system in multiple forms, ranging in oxidation states from +6 to –2. It is an essential element of life and participates in numerous microbially driven redox processes. In the modern ocean, dissolved sulfate is the most abundant form of sulfur with a concentration of 29 mM (Canfield, 2001a). Only a few oceanic basins, most prominently the Black Sea, exhibit a permanent stratification of the water body characterized by an anoxic lower part of the water column where dissolved sulfide is stable; such a water body is termed euxinic. Modern marine sediments contain dissolved sulfate and sulfide in their porewaters, the latter resulting from microbially driven sulfate reduction. Dissolved sulfide generally combines with reduced iron to form sedimentary iron sulfide (Rickard and Luther, 2007). In ancient sedimentary rocks, sulfur is most prominently present as sulfate mineral (gypsum, anhydrite, barite), as carbonate‐associated sulfate (CAS), as sedimentary iron sulfide (pyrite), or as organic‐bound sulfur.

      This review will address key aspects of the global sulfur cycle, as recorded by the sulfur isotopic composition and archived in marine sediments. Starting with the modern ocean, different aspects of sulfur cycling on different spatial and temporal scales archived in the marine sedimentary sulfur isotope record will be explored.

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